Vibronic sensor and measuring assembly for monitoring a flowable medium

The invention claimed is: 1. A vibronic sensor for monitoring a flowable medium, comprising: an oscillator to which a medium surrounding the oscillator can be applied; at least one electromechanical transducer for exciting said oscillator to mechanical vibrations in accordance with driver signals, and/or for outputting transducer signals that depend upon vibrations of said oscillator; and an operating and evaluating unit for providing the driver signals for driving said at least one electromechanical transducer, for capturing the transducer signals, and for determining the presence, the density, and/or the viscosity of the medium in accordance with the transducer signals, wherein: said oscillator has an oscillating fork, a paddle, or a rod; the oscillator forms a flow obstruction at which, in a flowing medium, eddies, due to which a vibration response of the oscillator is influenced, separate with a velocity-proportional separation frequency of the of eddies; an amplitude of pressure fluctuations due to the eddies is, at a first approximation, proportional to the square of the flow velocity; a measurable superposition of the resonator vibrations of the oscillator with forced vibrations due to the eddies occurs with increasing flow rate, thereby yielding periodic time-variable modifications of the transducer signals, given a constant flow velocity of the medium above a limit value; the operating and evaluating unit is set up to determine values for at least one characteristic quantity of the vibrations of the oscillator, using the transducer signals of multiple vibration periods of the oscillator, and to perform a statistical analysis of the values of the at least one characteristic quantity, in order to detect said periodic modifications of the transducer signals, wherein the characteristic quantity is selected from the frequency of the transducer signals, a period of the transducer signals, an amplitude of the transducer signals, or a phase relationship between the driver signals and the transducer signals; the statistical analysis includes determining one of a width of a distribution of the values of the characteristic quantity; or a mean deviation between successive values of the characteristic quantity; said operating and evaluating unit is set up to detect whether the medium in the pipe has a flow velocity above said limit value on the basis of said statistical analysis of said time-variable modifications of said transducer signals. 2. The vibronic sensor according to claim 1 , wherein: the statistical analysis includes determining the mean deviation between successive values of the characteristic quantity. 3. The vibronic sensor according to claim 1 , wherein: said operating and evaluating unit has a microprocessor which is set up to perform the above statistical analyses on digitized transducer signals, to establish and signal a flow rate, and, if applicable, to determine and output an associated flow-rate measurement value. 4. A measuring assembly, comprising: a pipe; and a vibronic sensor for monitoring a flowable medium, comprising: an oscillator to which a medium surrounding the oscillator can be applied; at least one electromechanical transducer for exciting said oscillator to mechanical vibrations in accordance with driver signals, and/or for outputting transducer signals that depend upon vibrations of said oscillator; and an operating and evaluating unit for providing the driver signals for driving said at least one electromechanical transducer, for capturing the transducer signals, and for determining the presence, the density, and/or the viscosity of the medium in accordance with the transducer signals, wherein: said oscillator has an oscillating fork, a paddle, or a rod; the oscillator forms a flow obstruction at which, in a flowing medium, eddies, due to which a vibration response of the oscillator is influenced, separate with a velocity-proportional separation frequency of the of eddies; an amplitude of pressure fluctuations due to the eddies is, at a first approximation, proportional to the square of the flow velocity; a measurable superposition of the resonator vibrations of the oscillator with forced vibrations due to the eddies occurs with increasing flow rate, thereby yielding periodic time-variable modifications of the transducer signals, given a constant flow velocity of the medium above a limit value; the operating and evaluating unit is set up to determine values for at least one characteristic quantity of the vibrations of the oscillator, using the transducer signals of multiple vibration periods of the oscillator, and to perform a statistical analysis of the values of the at least one characteristic quantity, in order to detect said periodic modifications of the transducer signals, wherein the characteristic quantity is selected from the frequency of the transducer signals, a period of the transducer signals, amplitude of the transducer signals, or a phase relationship between the driver signals and the transducer signals; the statistical analysis includes determining one of a width of a distribution of the values of the characteristic quantity; or a mean deviation between successive values of the characteristic quantity; said operating and evaluating unit is set up to detect whether the medium in the pipe has a flow velocity above said limit value on the basis of said statistical analysis of said time-variable modifications of said transducer signals; and said vibronic sensor protrudes into the pipe. 5. The measuring assembly according to claim 4 , wherein: the pipe has a pipe wall; the vibronic sensor protrudes through a segment of said pipe wall, and essentially orthogonal to said pipe wall, into the pipe. 6. The measuring assembly according to claim 5 , wherein: the oscillator can be excited to vibration essentially at right angles to the segment of said pipe wall. 7. The measuring arrangement according to claim 5 , wherein: the oscillator can be excited to vibration essentially at right angles to the longitudinal axis of said measurement pipe. 8. The measuring assembly according to claim 5 , wherein: the oscillator can be excited to vibration essentially parallel to the longitudinal axis of said measurement pipe. 9. The measuring assembly according to claim 4 , wherein: the operating and evaluating unit has a data storage in which is stored a model that describes a link, specific to the measuring assembly, between the flow rate and the time-variable modifications of the transducer signals for at least one medium. 10. The vibronic sensor according to claim 1 , wherein: said oscillator has a resonance frequency which depends upon the density of the medium; and the limit value for the flow velocity is selected so that the frequency of the periodic modifications, given a flow velocity that corresponds to the limit value, is not more than one-fourth of the resonance frequency of the oscillator. 11. The vibronic sensor according to claim 1 , wherein: said oscillator has a resonance frequency which depends upon the density of the medium; and the limit value for the flow velocity is selected so that the frequency of the periodic modifications, given a flow velocity that corresponds to the limit value, is not more than one-eighth of the resonance frequency of the oscillator.